Articles citing this paper
Genetic variation in tolerance to the osmotic stress componentof salinity stress in durum wheat
Richard A. James A D , Susanne von Caemmerer B , A. G. (Tony) Condon A , Alexander B. Zwart C and Rana Munns A
+ Author Affiliations
- Author Affiliations
A CSIRO Plant Industry, GPO Box 1600, Canberra, ACT 2601, Australia.
B Research School of Biological Sciences, Australian National University, Canberra, ACT 0200, Australia.
C CSIRO Mathematical and Information Sciences, GPO Box 664, Canberra, ACT 2601, Australia.
D Corresponding author. Email: richard.james@csiro.au
Functional Plant Biology 35(2) 111-123 https://doi.org/10.1071/FP07234
Submitted: 4 October 2007 Accepted: 6 February 2008 Published: 19 March 2008
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Munns R.,
James R. A.,
Sirault X. R. R.,
Furbank R. T., Jones H. G.
Journal of Experimental Botany. 2010 61(13). p.3499
Stomatal conductance as a screen for osmotic stress tolerance in durum wheat growing in saline soil
Rahnama Afrasyab,
James Richard A.,
Poustini Kazem, Munns Rana
Functional Plant Biology. 2010 37(3). p.255
Elucidation of Abiotic Stress Signaling in Plants (2015)
The resistance of plants Setaria veridis (L.) Beauv. to the influence of cadmium
Kaznina N. M.,
Titov A. F.,
Batova Yu. V., Laidinen G. F.
Biology Bulletin. 2014 41(5). p.428
Shoot δ15N gives a better indication than ion concentration or Δ13C of genotypic differences in the response of durum wheat to salinity
Yousfi Salima,
Serret Maria Dolores, Araus José Luis
Functional Plant Biology. 2009 36(2). p.144
Different responses of photosystem and antioxidant defense system to three environmental stresses in wheat seedlings
WU N.,
MAO H.T.,
CHEN M.Y.,
DONG J.,
YUAN M.,
ZHANG Z.W.,
YUAN S.,
ZHANG H.Y., CHEN Y.E.
Photosynthetica. 2020 58(1). p.87
Salinity Duration Differently Modulates Physiological Parameters and Metabolites Profile in Roots of Two Contrasting Barley Genotypes
Dell’Aversana Emilia,
Hessini Kamel,
Ferchichi Selma,
Fusco Giovanna Marta,
Woodrow Pasqualina,
Ciarmiello Loredana F.,
Abdelly Chedly, Carillo Petronia
Plants. 2021 10(2). p.307
Dissecting the genetic and phenotypic basis of salinity tolerance in mungbean: insights from multi-stage phenotyping, GWAS and genomic prediction
Iqbal Md Shahin,
Taylor Candy M.,
Kotula Lukasz,
Malik Al Imran, Erskine William
Theoretical and Applied Genetics. 2025 138(9).
Use of genetic tolerance in grain crops to overcome subsoil constraints in alkaline cropping soils
Nuttall J. G.,
Hobson K. B.,
Materne M.,
Moody D. B.,
Munns R., Armstrong R. D.
Soil Research. 2010 48(2). p.188
Root Growth and Architecture Responses of Bread Wheat Cultivars to Salinity Stress
Rahnama Afrasyab,
Fakhri Shokooh, Meskarbashee Moosa
Agronomy Journal. 2019 111(6). p.2991
Response of six garden roses (Rosa×hybrida L.) to salt stress
Cai Xiaoya,
Niu Genhua,
Starman Terri, Hall Charles
Scientia Horticulturae. 2014 168 p.27
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Rahnama Afrasyab,
Munns Rana,
Poustini Kazem, Watt Michelle
Journal of Experimental Botany. 2011 62(1). p.69
A comparison of hydroponic and soil-based screening methods to identify salt tolerance in the field in barley
Tavakkoli Ehsan,
Fatehi Foad,
Rengasamy Pichu, McDonald Glenn K.
Journal of Experimental Botany. 2012 63(10). p.3853
The response of drought-tolerant sugar beet to salinity stress under field and controlled environmental conditions
Abbasi Zahra,
Golabadi Maryam,
Khayamim Samar, Pessarakli Mohammad
Journal of Plant Nutrition. 2018 41(20). p.2660
Encyclopedia of Sustainability Science and Technology (2012)
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Finnie Jeffrey F., Van Staden Johannes
Plant Physiology and Biochemistry. 2013 65 p.102
Combined use of δ13C, δ18O and δ15N tracks nitrogen metabolism and genotypic adaptation of durum wheat to salinity and water deficit
Yousfi Salima,
Serret Maria Dolores,
Márquez Antonio José,
Voltas Jordi, Araus José Luis
New Phytologist. 2012 194(1). p.230
Use of thermography for high throughput phenotyping of tropical maize adaptation in water stress
Romano Giuseppe,
Zia Shamaila,
Spreer Wolfram,
Sanchez Ciro,
Cairns Jill,
Araus Jose Luis, Müller Joachim
Computers and Electronics in Agriculture. 2011 79(1). p.67
Hormonal regulation of source - sink relations to maintain crop productivity under salinity: a case study of root-to-shoot signalling in tomato
Pérez-Alfocea Francisco,
Albacete Alfonso,
Ghanem Michel E., Dodd Ian C.
Functional Plant Biology. 2010 37(7). p.592
Plant Stress Tolerance (2010)
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Plants. 2020 9(10). p.1266
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Tounsi Sana,
Giorgi Debora,
Kuzmanović Ljiljana,
Jrad Olfa,
Farina Anna,
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Xu Wei,
Ahmed Naeem,
Yu Anmin,
Wang Zaiqing, Liu Aizhong
Plant and Cell Physiology. 2020 61(6). p.1120
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Cho Jung-Il,
Park Sung-Han,
Kwon Taek-Ryoun,
Lee Gang-Seob,
Jeong Mi-Jeong,
Kim Kyung-Whan,
Lee Seong-Kon, Park Soo-Chul
Acta Botanica Croatica. 2014 73(1). p.312
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An infrared-based coefficient to screen plant environmental stress: concept, test and applications
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Omasa Kenji, Sase Sadanori
Functional Plant Biology. 2009 36(11). p.990
Characterising variation in wheat traits under hostile soil conditions in India
Khokhar Jaswant S.,
Sareen Sindhu,
Tyagi Bhudeva S.,
Singh Gyanendra,
Chowdhury Apurba K.,
Dhar Tapamay,
Singh Vinod,
King Ian P.,
Young Scott D.,
Broadley Martin R., Prasad Manoj
PLOS ONE. 2017 12(6). p.e0179208
Innovative Saline Agriculture (2016)
Physiological and biochemical perspectives of non-salt tolerant plants during bacterial interaction against soil salinity
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Plant Physiology and Biochemistry. 2017 116 p.116
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Yamamoto Ryo, Miyazawa Yoshiyuki
Plant Methods. 2024 20(1).
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Bardisi Enas,
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Journal of Plant Physiology. 2014 171(5). p.64
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Buyyarapu Ramesh,
Guttikonda Satish K.,
Parliament Kelly,
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Tokarz Krzysztof Michał,
Szymańska Renata,
Niewiadomska Ewa,
Rozpądek Piotr, Wątor Katarzyna
International Journal of Molecular Sciences. 2021 22(9). p.4663
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Dunlevy J.D.,
Blackmore D.H.,
Betts A.,
Jewell N.,
Brien C.,
Berger B.,
Walker R.R.,
Edwards E. J., Walker A.R.
Australian Journal of Grape and Wine Research. 2022 28(2). p.276
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Moon Jun-Cheol,
Chapagain Sandeep,
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Kim Jung Ju, Jang Cheol Seong
Environmental and Experimental Botany. 2018 155 p.21
Drought stress during maize flowering may cause kernel abortion by inhibition of plasma membrane H+‐ATPase activity
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Cai Shengguan,
Zeng Fanrong,
Qiu Boyin, Zhang Guoping
Journal of Plant Nutrition. 2012 35(6). p.827
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Bazihizina Nadia,
Giordano Cristiana,
Mancuso Stefano,
Azzarello Elisa, Ball Marilyn
Tree Physiology. 2017 37(3). p.380
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Sharp Robert E.,
Tester Mark, Bacic Antony
Functional Plant Biology. 2013 40(5). p.516
Infrared imaging indices for genotype screening in plant drought responses
Kurumayya Venkatesha
Acta Physiologiae Plantarum. 2023 45(11).
Transcriptional variation is associated with differences in shoot sodium accumulation in distinct barley varieties
Amarasinghe Shanika L.,
Watson-Haigh Nathan S.,
Byrt Caitlin,
James Richard,
Qiu Jiaen,
Berkowitz Oliver,
Whelan James,
Roy Stuart J.,
Gilliham Matthew, Baumann Ute
Environmental and Experimental Botany. 2019 166 p.103812
Intensified Land and Water Use (2021)
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Journal of Plant Nutrition. 2012 35(9). p.1314
Grapevine varieties exhibiting differences in stomatal response to water deficit
Costa Joaquim M.,
Ortuño Maria F.,
Lopes Carlos M., Chaves Maria M.
Functional Plant Biology. 2012 39(3). p.179
Comparison of Salt and Drought‐Stress Effects on Maize Growth and Yield Formation with Regard to Acid Invertase Activity in the Kernels
Hütsch B. W.,
Jung S., Schubert S.
Journal of Agronomy and Crop Science. 2015 201(5). p.353
Stomatal Conductance Is Essential for Higher Yield Potential of C3Crops
Roche Dominique
Critical Reviews in Plant Sciences. 2015 34(4). p.429
Biotic and Abiotic Stress Tolerance in Plants (2018)
(2013)
(2014)
Soil Conditions and Plant Growth (2013)
Variation in shoot tolerance mechanisms not related to ion toxicity in barley
Tilbrook Joanne,
Schilling Rhiannon K.,
Berger Bettina,
Garcia Alexandre F.,
Trittermann Christine,
Coventry Stewart,
Rabie Huwaida,
Brien Chris,
Nguyen Martin,
Tester Mark, Roy Stuart J.
Functional Plant Biology. 2017 44(12). p.1194
Ion concentration and energy response of two wheat cultivars to salt stress
Poustini Kazem,
Esmaeili Alireza,
Abbasi Alireza, Sadeghpour Amir
Journal of Plant Nutrition. 2020 43(10). p.1447
Investigating the Role of Respiration in Plant Salinity Tolerance by Analyzing Mitochondrial Proteomes from Wheat and a Salinity-Tolerant Amphiploid (Wheat × Lophopyrum elongatum)
Jacoby Richard P.,
Millar A. Harvey, Taylor Nicolas L.
Journal of Proteome Research. 2013 12(11). p.4807
The response of barley to salinity stress differs between hydroponic and soil systems
Tavakkoli Ehsan,
Rengasamy Pichu, McDonald Glenn K.
Functional Plant Biology. 2010 37(7). p.621
Host-targeted salt stress affects fitness and vector performance of bird cherry-oat aphid (Rhopalosiphum padi L.) on wheat
Ghodoum Parizipour Mohamad Hamed,
Rajabpour Ali,
Jafari Siroos, Tahmasebi Aminallah
Arthropod-Plant Interactions. 2021 15(1). p.47
How Does Stomatal Density and Residual Transpiration Contribute to Osmotic Stress Tolerance?
Hasanuzzaman Md.,
Zhou Meixue, Shabala Sergey
Plants. 2023 12(3). p.494
Photosynthetic responses of a wheat (Asakaze)-barley (Manas) 7H addition line to salt stress
Szopkó D.,
Darkó É.,
Molnár I.,
Kruppa K.,
Háló B.,
Vojtkó A.,
Molnár-Láng M., Dulai S.
Photosynthetica. 2017 55(2). p.317
Ethylene: A Master Regulator of Salinity Stress Tolerance in Plants
Riyazuddin Riyazuddin,
Verma Radhika,
Singh Kalpita,
Nisha Nisha,
Keisham Monika,
Bhati Kaushal Kumar,
Kim Sun Tae, Gupta Ravi
Biomolecules. 2020 10(6). p.959
Genomic approaches to enhance adaptive plasticity to cope with soil constraints amidst climate change in wheat
Bhoite Roopali,
Han Yong,
Chaitanya Alamuru Krishna,
Varshney Rajeev K., Sharma Darshan Lal
The Plant Genome. 2024 17(1).
Use of infrared thermal imaging to diagnose health of Ammopiptanthus mongolicus in northwestern China
Yuan Weijie,
Yu Yi,
Yue Yongde,
Wang Ji,
Zhang Fengchun, Dang Xiaohong
Journal of Forestry Research. 2015 26(3). p.605
From Genetic Maps to QTL Cloning: An Overview for Durum Wheat
Colasuonno Pasqualina,
Marcotuli Ilaria,
Gadaleta Agata, Soriano Jose Miguel
Plants. 2021 10(2). p.315
Plant Salt Tolerance (2012)
The impact of soil salinity on the yield, composition and physiology of the bioenergy grass Miscanthus × giganteus
Stavridou Evangelia,
Hastings Astley,
Webster Richard J., Robson Paul R. H.
GCB Bioenergy. 2017 9(1). p.92
Uncoupling of sodium and chloride to assist breeding for salinity tolerance in crops
Genc Yusuf,
Oldach Klaus,
Taylor Julian, Lyons Graham H.
New Phytologist. 2016 210(1). p.145
Evolution of halophytes: multiple origins of salt tolerance in land plants
Flowers Timothy J.,
Galal Hanaa K., Bromham Lindell
Functional Plant Biology. 2010 37(7). p.604
Image-based phenotyping for non-destructive screening of different salinity tolerance traits in rice
Hairmansis Aris,
Berger Bettina,
Tester Mark, Roy Stuart John
Rice. 2014 7(1).
Quantifying the three main components of salinity tolerance in cereals
RAJENDRAN KARTHIKA,
TESTER MARK, ROY STUART J.
Plant, Cell & Environment. 2009 32(3). p.237
A new screening method for osmotic component of salinity tolerance in cereals using infrared thermography
Sirault Xavier R. R.,
James Richard A., Furbank Robert T.
Functional Plant Biology. 2009 36(11). p.970
The Effects of NaCl Treatment on Water Relations, Growth, and ABA Content in Barley Cultivars Differing in Drought Tolerance
Veselov D. S.,
Sharipova G. V.,
Veselov S. U., Kudoyarova G. R.
Journal of Plant Growth Regulation. 2008 27(4). p.380
Evaluating physiological responses of plants to salinity stress
Negrão S.,
Schmöckel S. M., Tester M.
Annals of Botany. 2017 119(1). p.1
Genetic variability for responses to short‐ and long‐term salt stress in vegetative sunflower plants
Céccoli Gabriel,
Eugenia Senn María,
Bustos Dolores,
Ismael Ortega Leandro,
Córdoba Alicia,
Vegetti Abelardo, Taleisnik Edith
Journal of Plant Nutrition and Soil Science. 2012 175(6). p.882
Use of IR thermography in screening wheat (Triticum aestivumL.) cultivars for salt tolerance
Esmaeili Alireza,
Poustini Kazem,
Ahmadi Hojat, Abbasi Alireza
Archives of Agronomy and Soil Science. 2017 63(2). p.161
Seed Priming Enhances Seed Germination and Morphological Traits of Lactuca sativa L. under Salt Stress
Adhikari Bikash,
Olorunwa Omolayo J., Barickman T. Casey
Seeds. 2022 1(2). p.74
Plant Stress Mitigators (2023)
Wild Germplasm for Genetic Improvement in Crop Plants (2021)
Silicon-mediated improvement in the salt resistance of wheat (Triticum aestivum) results from increased sodium exclusion and resistance to oxidative stress
Saqib Muhammad,
Zörb Christian, Schubert Sven
Functional Plant Biology. 2008 35(7). p.633
Major genes for Na+ exclusion, Nax1 and Nax2 (wheat HKT1;4 and HKT1;5), decrease Na+ accumulation in bread wheat leaves under saline and waterlogged conditions
James R. A.,
Blake C.,
Byrt C. S., Munns R.
Journal of Experimental Botany. 2011 62(8). p.2939
Stress Responses in Plants (2015)
Disentangling the contributions of osmotic and ionic effects of salinity on stomatal, mesophyll, biochemical and light limitations to photosynthesis
CHEN TSU‐WEI,
KAHLEN KATRIN, STÜTZEL HARTMUT
Plant, Cell & Environment. 2015 38(8). p.1528
Opportunity and challenges of phenotyping plant salt tolerance
Hu Yuncai, Schmidhalter Urs
Trends in Plant Science. 2023 28(5). p.552
Moderate NaCl alleviates osmotic stress in Lycium ruthenicum
Hu Jing,
Hu Xiaoke,
Zhang Huiwen, Yu Qiushi
Plant Growth Regulation. 2022 96(1). p.25
Growth responses of Atriplex lentiformis and Medicago arborea in three soil types treated with saline water irrigation
Panta Suresh,
Flowers Tim,
Doyle Richard,
Lane Peter,
Haros Gabriel, Shabala Sergey
Environmental and Experimental Botany. 2016 128 p.39
Tissue tolerance: an essential but elusive trait for salt-tolerant crops
Munns Rana,
James Richard A.,
Gilliham Matthew,
Flowers Timothy J., Colmer Timothy D.
Functional Plant Biology. 2016 43(12). p.1103
Rhizosphere bacteria containing 1-aminocyclopropane-1- carboxylate deaminase increase growth and photosynthesis of pea plants under salt stress by limiting Na+ accumulation
Wang Qiyuan,
Dodd Ian C.,
Belimov Andrey A., Jiang Fan
Functional Plant Biology. 2016 43(2). p.161
Probiotics and Plant Health (2017)
Comparison on Photosynthesis and Antioxidant Defense Systems in Wheat with Different Ploidy Levels and Octoploid Triticale
Mao Haotian,
Chen Mengying,
Su Yanqiu,
Wu Nan,
Yuan Ming,
Yuan Shu,
Brestic Marian,
Zivcak Marek,
Zhang Huaiyu, Chen Yanger
International Journal of Molecular Sciences. 2018 19(10). p.3006
High temperature and vapor pressure deficit aggravate architectural effects but ameliorate non-architectural effects of salinity on dry mass production of tomato
Chen Tsu-Wei,
Nguyen Thi M. N.,
Kahlen Katrin, Stützel Hartmut
Frontiers in Plant Science. 2015 6
Genetic basis of ion exclusion in salinity stressed wheat: implications in improving crop yield
Naeem Muhammad,
Iqbal Muhammad,
Shakeel Amir,
Ul-Allah Sami,
Hussain Manzoor,
Rehman Abdur,
Zafar Zafar Ullah,
Athar Habib-ur-Rehman, Ashraf Muhammad
Plant Growth Regulation. 2020 92(3). p.479
Zinc in Plants (2025)
Selection of plant physiological parameters to detect stress effects in pot experiments using principal component analysis
Füzy Anna,
Kovács Ramóna,
Cseresnyés Imre,
Parádi István,
Szili-Kovács Tibor,
Kelemen Bettina,
Rajkai Kálmán, Takács Tünde
Acta Physiologiae Plantarum. 2019 41(5).
(2019)
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Sade Nir,
Weng Fei,
Tajima Hiromi,
Zeron Yarden,
Zhang Lei,
Rubio Wilhelmi Maria del Mar,
Day George,
Peleg Zvi, Blumwald Eduardo
Plants. 2020 9(10). p.1383
Plant Abiotic Stress (2013)
Growth Properties and Ion Distribution in Different Tissues of Bread Wheat Genotypes (Triticum aestivum L.) Differing in Salt Tolerance
Rahnama A.,
Poustini K.,
Tavakkol-Afshari R.,
Ahmadi A., Alizadeh H.
Journal of Agronomy and Crop Science. 2011 197(1). p.21
Bioresource Technology (2022)
Encyclopedia of Sustainability Science and Technology (2019)
Genetic behaviour of physiological traits conferring cytosolic K+/ Na+ homeostasis in wheat
Cuin T. A.,
Zhou M.,
Parsons D., Shabala S.
Plant Biology. 2012 14(3). p.438
Saline and Alkaline Soils in Latin America (2021)
Salt stress resilience in plants mediated through osmolyte accumulation and its crosstalk mechanism with phytohormones
Singh Pooja,
Choudhary Krishna Kumar,
Chaudhary Nivedita,
Gupta Shweta,
Sahu Mamatamayee,
Tejaswini Boddu, Sarkar Subrata
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Shelden Megan C.,
Dias Daniel A.,
Jayasinghe Nirupama S.,
Bacic Antony, Roessner Ute
Journal of Experimental Botany. 2016 67(12). p.3731
Effect of spent tea waste, compost and biochar on some growth parameters and concentration of nitrogen, phosphorus and potassium in spinach (
Spinacia oleracea
L.) under salinity stress
Abdolahi Arshad Mohammad,
Rangzan Nafiseh, Nadian Ghomsheh Habibollah
Journal of Plant Nutrition. 2024 47(7). p.1029
Effect of salt stress on photosynthesis and physiological parameters of three contrasting barley genotypes
Mahlooji M.,
Seyed Sharifi R.,
Razmjoo J.,
Sabzalian M. R., Sedghi M.
Photosynthetica. 2018 56(2). p.549
Development of single-nucleotide polymorphism markers of salinity tolerance for Tunisian durum wheat using RNA sequencing
Kim Sang Heon,
Kim Dae Yeon,
Yacoubi Inés, Seo Yong Weon
Acta Agriculturae Scandinavica, Section B — Soil & Plant Science. 2021 71(1). p.28
Durum wheat salt tolerance in relation to physiological, yield and quality characters
Borrelli G.,
Ficco D.,
Giuzio L.,
Pompa M.,
Cattivelli L., Flagella Z.
Cereal Research Communications. 2011 39(4). p.525
Under salt stress guard cells rewire ion transport and abscisic acid signaling
Karimi Sohail M.,
Freund Matthias,
Wager Brittney M.,
Knoblauch Michael,
Fromm Jörg,
M. Mueller Heike,
Ache Peter,
Krischke Markus,
Mueller Martin J.,
Müller Tobias,
Dittrich Marcus,
Geilfus Christoph‐Martin,
Alfarhan Ahmed H.,
Hedrich Rainer, Deeken Rosalia
New Phytologist. 2021 231(3). p.1040
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Journal of Experimental Botany. 2013 64(1). p.119
Phenomics in Crop Plants: Trends, Options and Limitations (2015)
Genotypic water-deficit stress responses in durum wheat: association between physiological traits, microRNA regulatory modules and yield components
Liu Haipei,
Able Amanda J., Able Jason A.
Functional Plant Biology. 2017 44(5). p.538
Determination of canopy‐shadow‐affected area in sparse steppes and its effects on evaporation and evapotranspiration
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Qiu Guo Yu, Zhang Qingtao
Ecohydrology. 2014 7(6). p.1589
